Multitasking in the gut: the X-ray structure of the multidomain BbgIII from Bifidobacterium bifidum offers possible explanations for its alternative functions

β-Galactosidases catalyse the hydrolysis of lactose into galactose and glucose; as an alternative reaction, some β-galactosidases also catalyse the formation of galactooligosaccharides by transglycosylation. Both reactions have industrial importance: lactose hydrolysis is used to produce lactose-free milk, while galactooligosaccharides have been shown to act as prebiotics. For some multi-domain β-galactosidases, the hydrolysis/transglycosylation ratio can be modified by the truncation of carbohydrate-binding modules. Here, an analysis of BbgIII, a multidomain β-galactosidase from Bifidobacterium bifidum, is presented. The X-ray structure has been determined of an intact protein corresponding to a gene construct of eight domains. The use of evolutionary covariance-based predictions made sequence docking in low-resolution areas of the model spectacularly easy, confirming the relevance of this rapidly developing deep-learning-based technique for model building. The structure revealed two alternative orientations of the CBM32 carbohydrate-binding module relative to the GH2 catalytic domain in the six crystallographically independent chains. In one orientation the CBM32 domain covers the entrance to the active site of the enzyme, while in the other orientation the active site is open, suggesting a possible mechanism for switching between the two activities of the enzyme, namely lactose hydrolysis and transgalactosylation. The location of the carbohydrate-binding site of the CBM32 domain on the opposite site of the module to where it comes into contact with the catalytic GH2 domain is consistent with its involvement in adherence to host cells. The role of the CBM32 domain in switching between hydrolysis and transglycosylation modes offers protein-engineering opportunities for selective β-galactosidase modification for industrial purposes in the future.

Identification and characterization of a bacterial glutamic peptidase

Background

Glutamic peptidases, from the MEROPS family G1, are a distinct group of peptidases characterized by a catalytic dyad consisting of a glutamate and a glutamine residue, optimal activity at acidic pH and insensitivity towards the microbial derived protease inhibitor, pepstatin. Previously, only glutamic peptidases derived from filamentous fungi have been characterized.

Results

We report the first characterization of a bacterial glutamic peptidase (pepG1), derived from the thermoacidophilic bacteria Alicyclobacillus sp. DSM 15716. The amino acid sequence identity between pepG1 and known fungal glutamic peptidases is only 24-30% but homology modeling, the presence of the glutamate/glutamine catalytic dyad and a number of highly conserved motifs strongly support the inclusion of pepG1 as a glutamic peptidase. Phylogenetic analysis places pepG1 and other putative bacterial and archaeal glutamic peptidases in a cluster separate from the fungal glutamic peptidases, indicating a divergent and independent evolution of bacterial and fungal glutamic peptidases. Purification of pepG1, heterologously expressed in Bacillus subtilis, was performed using hydrophobic interaction chromatography and ion exchange chromatography. The purified peptidase was characterized with respect to its physical properties. Temperature and pH optimums were found to be 60°C and pH 3-4, in agreement with the values observed for the fungal members of family G1. In addition, pepG1 was found to be pepstatin-insensitive, a characteristic signature of glutamic peptidases.

Conclusions

Based on the obtained results, we suggest that pepG1 can be added to the MEROPS family G1 as the first characterized bacterial member.

[A multi-centre study of the reliability, validity and sensitivity to change of the honos65+ in psychiatry for older persons]

BACKGROUND

Within the mental health care services for older persons there is a growing need for insight into and evaluation of the results of clinical treatment. The Health of the Nations Outcome Scales 65+ (honos65+) is a promising instrument for the assessment of mental, social and physical health in older persons, but it is not yet known whether it is valid for older persons in the Netherlands.

AIM

To assess the reliability, validity and sensibility to change of the honos65+ when applied to older persons with psychiatric disorders.

METHOD

The bio-psycho-social level of functioning of clients aged 60 and over (n=168) receiving mental health care was assessed by means of existing and validated measuring instruments and the results were compared with those obtained with the honos65+. Three months later the population sample was re-assessed in order to test the extent to which the honos65+ was sensitive to change.

RESULTS

The reliability and validity of the honos65+ could be ascertained for 168 clients aged 60 and over. After three months 116 clients were re-assessed so that the sensitivity of the honos65+ to change could be noted.

CONCLUSION

The honos65+ is a reliable and valid instrument for assessing clients with affective disorders such as depression and anxiety and for detecting changes in clients’ problems and functioning. No conclusions could be reached regarding the reliability and validity of the honos65+ when used for clients with other psychiatric disorders because the clinical subgroups were too small for patterns to be detected.

Colanic acid is an exopolysaccharide common to many enterobacteria isolated from paper-machine slimes

In this study, polysaccharide-producing bacteria were isolated from slimes collected from two Finnish and one Spanish paper mill and the exopolysaccharides (EPSs) produced by 18 isolates were characterised. Most of the isolates, selected on the bases of slimy colony morphology, were members of the family Enterobacteriaceae most frequently belonging to the genera Enterobacter and Klebsiella including Raoultella. All of the EPSs analysed showed the presence of charged groups in the form of uronic acid or pyruvate revealing the polyanionic nature of these polysaccharides. Further results of the carbohydrate analysis showed that the EPS produced by nine of the enterobacteria was colanic acid.

Development of in vitro transposon assisted signal sequence trapping and its use in screening Bacillus halodurans C125 and Sulfolobus solfataricus P2 gene libraries

To identify genes encoding extracytosolic proteins, a minitransposon, TnSig, containing a signal-less beta-lactamase ('bla) as reporter gene, was constructed and used for in vitro transposition of genomic libraries made in Escherichia coli. The 'bla gene was cloned into a bacteriophage Mu minitransposon enabling translational fusions between 'bla and target genes. Fusion of TnSig in the correct reading frame to a protein carrying transmembrane domains or signal peptides resulted in ampicillin resistance of the corresponding clone. Prokaryotic gene libraries from the alkaliphilic bacterium Bacillus halodurans C125 and the hyperthermophilic archaeon Sulfolobus solfataricus P2 were tagged with TnSig. The genomic sequences, which are publicly available (EMBL and EMBL ), were used for rapid open reading frame (ORF) identification and prediction of protein localisation in the cell. Genes for secreted proteins, transmembrane proteins and lipoproteins were successfully identified by this method. In contrast to previous transposon based identification strategies, the method described here is fast and versatile and essentially enables any selectable marker compatible library to be tagged. It is suited for identifying genes encoding extracytosolic proteins in gene libraries of a wide range of prokaryotic organisms.

Preparation of a crystallizable mRNA-binding fragment of Moorella thermoacetica elongation factor SelB

SelB is a bacterial elongation factor required for the decoding of a UGA stop codon together with a specific mRNA hairpin to selenocysteine. In attempts to crystallize Moorella thermoacetica SelB, a proteolysis process occurred and crystals of a proteolytic fragment were observed. The crystals, which appeared after a year, contained a C-terminal 30 kDa fragment containing the mRNA-binding domain. This fragment was reproduced through recloning. Crystals diffracting to 2.7 A were obtained.

Selenoprotein synthesis in archaea

The availability of the genome sequences from several archaea has facilitated the identification of the encoded selenoproteins and also of most of the components of the machinery for selenocysteine biosynthesis and insertion. Until now, selenoproteins have been identified solely in species of the genera Methanococcus (M.) and Methanopyrus. Apart from selenophosphate synthetase, they include only enzymes with a function in energy metabolism. Like in bacteria and eukarya, selenocysteine insertion is directed by a UGA codon in the mRNA and involves the action of a specific tRNA and of selenophosphate as the selenium donor. Major differences to the bacterial system, however, are that no homolog for the bacterial selenocysteine synthase was found and, especially, that the SECIS element of the mRNA is positioned in the 3' nontranslated region. The characterisation of a homolog for the bacterial SelB protein showed that it does not bind to the SECIS element necessitating the activity of at least a second protein. The use of the genetic system of M. maripaludis allowed the heterologous expression of a selenoprotein gene from M. jannaschii and will facilitate the elucidation of the mechanism of the selenocysteine insertion process in the future.

Identification and characterisation of the selenocysteine-specific translation factor SelB from the archaeon Methanococcus jannaschii

Selenocysteine insertion into archaeal selenopolypeptides is directed through an mRNA structure (the SECIS element) situated in the 3' non-translated region like in eukaryotes. To elucidate the mechanism how this element affects decoding of an in-frame UGA with selenocysteine the open reading frames of the genome of Methanococcus jannaschii were searched for the existence of a homolog to the bacterial specialized translation factor SelB. The product of the open reading frame MJ0495 was identified as the archaeal SelB homolog on the basis of the following characteristics: (1) MJ0495 possesses sequence features characteristic of bacterial SelB; (2) purified MJ0495 displays guanine nucleotide binding properties like SelB; and (3) it preferentially binds selenocysteyl-tRNA(Sec). In contrast to bacterial SelB, however, no binding of MJ0495 protein to the SECIS element of the mRNA was found under the experimental conditions employed which correlates with the fact that MJ0495 lacks the C-terminal domain of the bacterial SelB protein known to bind the SECIS element. It is speculated that in Archaea the functions of bacterial SelB are distributed over at least two proteins, one, serving as the specific translation factor, like MJ0495, and another one, binding to the SECIS which interacts with the ribosome and primes it to decode UGA.

Bacterial selenocysteine synthase--structural and functional properties

Selenocysteine synthase from Escherichia coli is a pyridoxal-5'-phosphate-containing enzyme which catalyses the conversion of seryl-tRNA(Sec) into selenocysteyl-tRNA(Sec). Analysis of amino acid sequences indicated that selenocysteine synthase belongs to the alpha/gamma superfamily of pyridoxal-5'-phosphate-dependent enzymes. To identify the lysine residue carrying the prosthetic group, the genes coding for the selenocysteine synthases from Moorella thermoacetica and Desulfomicrobium baculatum were cloned and sequenced and their derived amino acid sequences were aligned with those from E. coli and Haemophilus influenzae. Three lysine residues were found to be conserved; they were mutated into asparagine and one of them, Lys295, was found to be essential for activity. Proteolytic fragmentation of the E. coli enzyme reduced with borohydride, and mass-spectrometric and sequence analysis of the chromophoric peptide proved that Lys295 was modified. Kinetic analysis of the enzyme showed that thiophosphate served as a substrate leading to cysteyl-tRNA(Sec) synthesis, albeit with a 330-fold lower catalytic efficiency. Selenide and, to a much lesser degree, sulfide could also be used by the enzyme but only at much higher concentrations. These data together with the finding that selenophosphate synthetase is highly specific for selenide indicate that the phosphate moiety of selenophosphate provides selenocysteine synthase with the discrimination specificity against sulfur.

Functional expression in Escherichia coli of the Haemophilus influenzae gene coding for selenocysteine-containing selenophosphate synthetase

The selenophosphate synthetases from several organisms contain a selenocysteine residue in their active site where the Escherichia coli enzyme contains a cysteine. The synthesis of these enzymes, therefore, depends on their own reaction product. To analyse how this self-dependence is correlated with the selenium status, e.g. after recovery from severe selenium starvation, we expressed the gene for the selenocysteine-containing selenophosphate synthetase from Haemophilus influenzae (selDHI) in an E. coli DeltaselD strain. Gene selDHI gave rise to a selenium-containing gene product and also supported - via its activity - the formation of E. coli selenoproteins. The results provide evidence either for the suppression of the UGASec codon with the insertion of an amino acid allowing the formation of a functional product or for a bypass of the selenophosphate requirement. We also show that the selenocysteine synthesis and the insertion systems of the two organisms are fully compatible despite conspicuous differences in the mRNA recognition motif.

Domain structure of the selenocysteine-specific translation factor SelB in prokaryotes

Translation factor SelB is the key component for the specific decoding of UGA codons with selenocysteine at the ribosome. SelB binds selenocysteyl-tRNA(Sec), guanine nucleotides and a secondary structure of the selenoprotein mRNA following the UGA at the 3' side. A comparison of the amino acid sequences of SelB species from E. coli, Desulfomicrobium baculatum, Clostridium thermoaceticum and Haemophilus influenzae showed that the proteins consist of at least four structural domains from which the N-terminal three are well conserved and share homology with elongation factor Tu whereas the C-terminal one is more variable and displays no similarity to any protein known. With the aid of the coordinates of EF-Tu the N-terminal part has been modelled into a 3D structure which exhibits intriguing features concerning its interaction with guanine nucleotides and other components of the translational apparatus. Cloning and expression of fragments of SelB and biochemical analysis of the purified truncated proteins showed that the C-terminal 19 kDa protein fragment is able to specifically bind to the selenoprotein mRNA. SelB, thus, is a translation factor functionally homologous to EF-Tu hooked up to the mRNA with its C-terminal end. The formation by SelB of a quaternary complex in vivo has been proven by overexpression of truncated genes of SelB and by demonstration that fragments comprising the mRNA or the tRNA binding domain inhibit selenocysteine insertion.

Selenoprotein synthesis in archaea: identification of an mRNA element of Methanococcus jannaschii probably directing selenocysteine insertion

Selenocysteine is encoded by a UGA codon in all organisms that synthesise selenoproteins. This codon is specified as a selenocysteine codon by an mRNA secondary structure, which is located immediately 3' of the UGA in the reading frame of selenoprotein genes in Gram-negative bacteria, whereas it is located in the 3' untranslated region of eukaryal selenoprotein genes. The location and the structure of a similar mRNA signal in archaea has so far not been determined. Seven selenoproteins were identified for the archaeon Methanococcus jannaschii by labelling with 75Se and by SDS/polyacrylamide electrophoresis. Their size could be correlated with open reading frames possessing internal UGA codons from the total genomic sequence. One of the open reading frames, that of the VhuD subunit of a hydrogenase, possesses two UGA codons and appears to code for a selenoprotein with two selenocysteine residues. A strongly conserved mRNA element was identified that is exclusively linked to selenoprotein genes. It is located in the 3' untranslated region in six of the mRNAs and in the 5' untranslated region of the fdhA mRNA. This element, which is present in the 3' non-translated region of two selenoprotein mRNAs from Methanococcus voltae, is proposed to act in decoding of the UGA with selenocysteine.

Domain structure of the prokaryotic selenocysteine-specific elongation factor SelB

Incorporation of the non-canonical amino acid selenocysteine into proteins requires the activity of the elongation factor SelB which substitutes for the function of EF-Tu in contrast to EF-Tu, SelB binds selenocystylated tRNASec and an mRNA secondary structure adjacent to the UGA selenocysteine codon. To gain information on the domain structure of this specialized translation factor, the selB genes from two bacteria unrelated to Escherichia coli (Clostridium thermoaceticum and Desulfomicrobium baculatum) were cloned and sequenced. The derived amino acid residue sequences were compared to those of SelB from E. coli and Haemophilus influenzae and to EF-Tu sequences. The alignment revealed that SelB contains all three domains characterized for EF-Tu. A fourth, C-terminally located domain shows only limited sequence conservation within the four SelB proteins. To elucidate the function of this C-terminal part a structure-function analysis of SelB from E. coli was performed. It showed that a C-terminal 17 kDa subdomain of the translation factor, when expressed separately, specifically binds the mRNA secondary structure. The recognition motif itself could be reduced to a 17 nucleotide minihelix without loss of binding affinity and specificity. A truncated SelB lacking the mRNA binding domain was still able to interact with selenocysteyl-tRNASec. Expression of the mRNA binding domain alone suppressed selenocysteine insertion in vivo by competing with SelB for its binding site at the mRNA. The results indicate that SelB can be considered as an EF-Tu homolog hooked to the mRNA via its C-terminal domain.

Structural model for the selenocysteine-specific elongation factor SelB

A structural model was established for the N-terminal part of translation factor SelB which shares sequence similarity with EF-Tu, taking into account the coordinates of the EF-Tu 3D structure and the consensus of SelB sequences from four bacteria. The model showed that SelB is homologous in its N-terminal domains over all three domains of EF-Tu. The guanine nucleotide binding site and the residues involved in GTP hydrolysis are similar to those of EF-Tu, but with some subtle differences possibly responsible for the higher affinity of SelB for GTP compared to GDP. In accordance, the EF-Tu epitopes interacting with EF-Ts are lacking in SelB. Information on the formation of the selenocysteyl-binding pocket is presented. A phylogenetic comparison of the SelB domains homologous to EF-Tu with those from EF-Tu and initiation factor 2 indicated that SelB forms a separate class of translation factors.

Genes coding for the selenocysteine-inserting tRNA species from Desulfomicrobium baculatum and Clostridium thermoaceticum: structural and evolutionary implications

The genes (selC) coding for the selenocysteine-inserting tRNA species (tRNA(Sec)) from Clostridium thermoaceticum and Desulfomicrobium baculatum were cloned and sequenced. Although they differ in numerous positions from the sequence of the Escherichia coli selC gene, they were able to complement the selC lesion of an E. coli mutant and to promote selenoprotein formation in the heterologous host. The tRNA(Sec) species from both organisms possess all of the unique primary, secondary, and tertiary structural features exhibited by E. coli tRNA(Sec) (C. Baron, E. Westhof, A. Böck, and R. Giegé, J. Mol. Biol. 231:274-292, 1993). The structural and functional properties of the tRNA(Sec) species from prokaryotes analyzed thus far support the notion that tRNA(Sec) may be an evolutionarily conserved structure whose function in the primordial genetic code was to decode UGA with selenocysteine.